Image processing apparatus, image forming apparatus, image processing method, and computer-readable storage medium containing image processing program

ABSTRACT

An image processing apparatus of the present invention uses a spatial filter section or an enlarging/reducing section to perform a blur process on image processing data to be supplied to an image display device, thus allowing the image display device to display a preview without deterioration in image quality.

This Nonprovisional application claims priority under 35 U.S.C. §119(a)on Patent Application No. 2008-218834 filed in Japan on Aug. 27, 2008,the entire contents of which are hereby incorporated by reference.

TECHNICAL FIELD

The present invention relates to an image processing apparatus, an imageforming apparatus, an image processing method, and a computer-readablestorage medium containing an image processing program, each of whichserves to display a thumbnail or preview of input image data.

BACKGROUND ART

Some image forming apparatuses such as copying machines andmultifunction printers display, in accordance with image data processedaccording to the type of document and the setting conditions (e.g.,print density, enlarging/reducing ratio, single-side printing/duplexprinting, margin size), a preview of a single image to be printed or acombination of images to be printed.

Such a preview display is described, for example, in Patent Literature1, which discloses a technique for generating a preview image withoutperforming edge enhancement on image data. This technique prevents ahigh-frequency component near the sampling frequency of an image displaydevice from being so amplified that only the moiré of a preview image isenhanced and the preview image therefore looks obviously different froman image to be outputted as a hard copy.

CITATION LIST

Patent Literature 1

Japanese Patent Application Publication, Tokukaihei, No. 9-135316 A(Publication Date: May 20, 1997)

SUMMARY OF INVENTION Technical Problem

For example, in the case of a preview display on a display of an imageread by a scanner whose resolution is 600 dpi or 1,200 dpi, it isnecessary to perform a process of downsampling (interpolating) pixels,because the resolution of the display is as low as, for example, 72 dpior 96 dpi and the image data are displayed to fit the size of the screenof the display. Here, in the case of a process of downsampling imagedata, image data composed of segmentation class signals cannot bedownsampled with interpolation such as a bilinear or bicubic method, butare simply downsampled. This causes a lack of image information in someinterpolated pixels, thus causing deterioration in image quality.

Such deterioration in image quality at the time of a preview displayoccurs in cases where, as in Patent Literature 1, no edge enhancementprocess is performed at the time of a preview display, as well as incases where an enhancement process is performed on image data. Further,such deterioration in image quality due to a lack of image informationoccurs both in a text document and a picture document.

It should be noted here that Patent Literature 1 describes performing asmoothing process during a picture mode. However, this is a processaccording to the type of document, but not a process that is implementedaccording to whether or not a preview is performed. That is, thesmoothing process of Patent Literature 1 is not intended to inhibit alack of image information at the time of a preview. As evidenced bythese points, the conventional technique cannot prevent a lack of imageinformation at the time of a preview display from causing deteriorationin image quality.

The present invention has been made in view of the foregoing problems,and it is an object of the present invention to provide an imageprocessing apparatus or the like capable of displaying a preview withoutdeterioration in image quality of image data.

Solution to Problem

In order to solve the foregoing problems, an image processing apparatusaccording to the present invention is an image processing apparatus forgenerating image processing data by performing image processing on inputimage data, for supplying the image processing data to a job apparatusthat executes an image print job, an image transmission job, or an imagefiling job, and for supplying the image processing data to an imagedisplay device for displaying a preview, the image processing apparatusincluding: a blur process section for performing a blur process on imageprocessing data to be supplied to the image display device.

Advantageous Effects of Invention

According to the foregoing arrangement, the job apparatus, whichexecutes an image print job, an image transmission job, or an imagefiling job, and the image display device, which displays a preview, areeach supplied with image processing data. It should be noted here thatimage processing data to be supplied to the image display device aresubjected to a blur process. Therefore, the blur process makes itpossible to display an image while inhibiting deterioration in imagequality even if a preview is displayed by an image display device whoseresolution is lower than the resolution at which the input image datahave been read.

Thus, the image processing apparatus according to the present inventionperforms a blur process on image processing data to be supplied to theimage display device, i.e., on data on a text and/or line art image aswell as a picture image, and as such, can inhibit deterioration in imagequality by reducing a lack of image information at the time of a previewdisplay on the image display device. This makes it possible to obtain aneasily viewable preview display.

For a fuller understanding of the nature and advantages of theinvention, reference should be made to the ensuing detailed descriptiontaken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram showing an image forming apparatus of thepresent embodiment and showing the flow of image data in a printingprocess in a copier mode and a full-color mode.

FIG. 2 shows block diagrams showing a part inside of an image processingapparatus (a) performing a printing process in the copier mode and asingle-color mode and (b) performing a printing process in the copiermode and a two-color mode.

FIG. 3 is a block diagram showing the image forming apparatus of thepresent embodiment and showing the flow of image data in a previewdisplay process in the copier mode and the full-color mode.

FIG. 4 shows block diagrams showing a part inside of the imageprocessing apparatus (a) performing a preview display in the copier modeand the singe-color mode and (b) performing a preview display in thecopier mode and the two-color mode.

FIG. 5 shows gamma curves, i.e., (a) an example of a gamma curvecorresponding to the display characteristics of an image display deviceand (b) a solid line representing a gamma curve for texts to be sharplydisplayed and a dotted line representing a gamma curve corresponding tothe display characteristics of the image display device.

FIG. 6 is a flow chart showing steps of a process that is performed bythe image forming apparatus in the copier mode and the full-color mode.

FIG. 7 is a block diagram showing the image forming apparatus of thepresent embodiment and showing the flow of image data in a transmissionprocess in a facsimile transmission mode.

FIG. 8 is a block diagram showing the image forming apparatus of thepresent embodiment and showing the flow of image data in a previewdisplay process in the facsimile transmission mode.

FIG. 9 is a block diagram showing the image forming apparatus of thepresent embodiment and showing the flow of image data in a printingprocess in a facsimile reception mode.

FIG. 10 is a block diagram showing the image forming apparatus of thepresent embodiment and showing the flow of image data in a previewdisplay process in the facsimile reception mode.

FIG. 11 is a block diagram showing a modification of the image formingapparatus of the present embodiment.

FIG. 12 is a block diagram detailing a spatial filter section of theimage forming apparatus of another embodiment.

FIG. 13 is a block diagram detailing a spatial filter section of theimage forming apparatus of another embodiment.

FIG. 14 is a block diagram detailing an enlarging/reducing section ofthe image forming apparatus of another embodiment.

DESCRIPTION OF EMBODIMENTS Embodiment 1

One embodiment of an image forming apparatus of the present invention isdescribed below with reference to the attached drawings. FIG. 1 is ablock diagram schematically showing an arrangement of an image formingapparatus 100 of the present embodiment.

The image forming apparatus 100 of the present embodiment is a digitalcolor multifunction printer that executes a mode selected from among acopier mode, a print mode, a facsimile transmission mode, a facsimilereception mode, and an image transmission mode.

The copier mode (copy mode) means a mode in which to read image data(generates image data by scanning a document) and print an image of theimage data onto a sheet of paper. The print mode means a mode in whichto print, onto a sheet of paper, an image of image data sent from aterminal apparatus connected to the image forming apparatus 100. Thefacsimile transmission mode means: a normal facsimile mode in which totransmit, to an external apparatus via a telephone line, image dataobtained by scanning a document; and an Internet facsimile mode in whichto transmit an e-mail with the image data attached thereto. Thefacsimile reception mode means a mode in which to receive image datafrom an external apparatus by facsimile and print an image of thereceived image data onto a sheet of paper. The image transmission modemeans: (1) a mode (scan to e-mail mode) in which to attach, to ane-mail, image data generated by scanning a document, and transmit thee-mail to a specified address; (2) a mode (scan to ftp mode) in which totransmit, to a folder specified by a user, image data generated byscanning a document; and (3) a mode (scan to usb mode) in which totransmit, to a USB memory mounted in the image forming apparatus 100,image data generated by scanning a document. It should be noted that thefacsimile transmission mode and the image transmission mode are eachclassified as above according to the type of image processing operation.

Further, in the copier mode or print mode, the user can select ablack-and-white mode in which to output a black-and-white image, afull-color mode in which to output a full-color image, a single-colormode in which to output a monochrome image having only one color desiredby the user, or a two-color mode in which to output a two-color imagehaving black and one color desired by the user.

For example, in cases where the user selects the single-color mode inthe copier mode or print mode, the monochromatic image is printed.Further, in cases where the user selects the two-color mode in thecopier mode or print mode, the two-color image is printed. It should benoted that in the single-color mode or two-color mode, the user selectshis/her desired color from among R (red), G (green), B (blue), C (cyan),M (magenta), and Y (yellow).

Further, according to the present invention it is possible to set anautomatic discrimination mode in the copier mode. In the automaticdiscrimination mode, the image forming apparatus 100 performs auto colorselection (ACS) for judging whether an object to be copied is a colordocument or a black-and-white document. In the case of a color document,the image forming apparatus 100 performs an output process in thefull-color mode. In the case of a black-and-white document, the imageforming apparatus 100 performs an output process in the black-and-whitemode.

As shown in FIG. 1, the image forming apparatus 100 includes an imageinput apparatus 101, an image processing apparatus 102, an image outputapparatus 103, an image display device 104, a receiving device 105, atransmitting device 106, a storage device 107, and a control section108.

The image input apparatus 101 is image scanning means for generatingimage data by scanning a document in the copier mode, the facsimiletransmission mode, and the image transmission mode. More specifically,the image input apparatus 101, which includes a scanner section having aCCD (charge-coupled device), converts light reflected by a document intoan electrical signal separated into colors RGB (i.e., into an analogimage signal) and sends the electrical signal to the image processingapparatus 102.

It should be noted that the image input apparatus 101 scans a documentimage in full color in any one of the full-color mode, the single-colormode, and the two-color mode. Further, the image input apparatus 101scans a document image in full color even in cases where the imageprocessing apparatus 102 performs the aforementioned auto colorselection.

The image processing apparatus 102 is an integrated circuit, constitutedby an ASIC (application specific integrated circuit), which performsimage processing on image data (image signals). As shown in FIG. 1, theimage processing apparatus 102 includes the following blocks: an A/D(analog/digital) conversion section 2, a shading correction section 3,an input processing section 4, an automatic document type discriminationsection 5, a segmentation process section 6, a compression (encode)section 7, a segmentation class signal compression (encode) section 8, adecompression (decode) section 9, a segmentation class signaldecompression (decode) section 10, an image-quality adjustment section11, a two-color printing process section 12, a color correction section13, a black generation and under color removal section 14, a spatialfilter section 15, an enlarging/reducing (zoom process) section 16, anoutput tone correction section 17, and a halftone generation section 18.Processes that are performed by the blocks of the image processingapparatus 102 will be detailed later.

In the copier mode, facsimile transmission mode, or image transmissionmode, the image processing apparatus 102 performs image processing onimage data sent from the image input apparatus 101. In the print mode,the image processing apparatus 102 performs image processing on imagedata transmitted from a terminal apparatus. In the facsimile receptionmode, the image processing apparatus 102 performs image processing onimage data received from an external apparatus. Then, in the copiermode, print mode, or facsimile reception mode, the image processingapparatus 102 transmits, to the image output apparatus 103, the imagedata subjected to image processing. In the facsimile transmission mode,the image processing apparatus 102 transmits, to the transmitting device106, the image data subjected to image processing. Further, in the scanto e-mail mode, which is an image transmission mode, the imageprocessing apparatus 102 transmits, to a mail processing section (notshown), the image data subjected to image processing. In the scan to ftpmode, which is another image transmission mode, the image processingapparatus 102 transmits, to a predetermined folder, the image datasubjected to image processing. In the scan to usb mode, which is theother image transmission mode, the image processing apparatus 102transmits, to a predetermined USB memory, the image data subjected toimage processing.

The image output apparatus (printer) 103 forms, onto a recording medium(e.g., a sheet of paper), an image of image data sent from the imageprocessing apparatus 102. An example is an electrophotographic orink-jet color printer. The term “printing” in the present embodimentmeans printing in the print mode, printing in the copier mode, orprinting in the facsimile reception mode.

The image display device 104 is a liquid crystal display provided in anoperation panel (not shown) of the image forming apparatus 100, and isdisplay means capable of displaying a color image. Further, the imagedisplay device 104, covered with a touch panel, functions as an inputinterface of the image forming apparatus 100. That is, the image displaydevice 104 displays a GUI for inputting various commands to the imageforming apparatus 100 and an operation guide.

Further, before execution of printing in the copier mode or facsimilereception mode, the image forming apparatus 100 of the presentembodiment can display, on the image display device 104, a preview of animage to be printed. Furthermore, before execution of transmission inthe facsimile transmission mode or image transmission mode, the imageforming apparatus 100 of the present embodiment can display, on theimage display device 104, a preview of an image to be transmitted.

Further, in the copier mode or image transmission mode and thefull-color mode, the image display device 104 displays a preview of afull-color image. In the copier mode or image transmission mode and thesingle-color mode, the image display device 104 displays a preview of amonochrome image. In the copier mode or image transmission mode and thetwo-color mode, the image display device 104 displays a preview of atwo-color image.

The image display device 104 is not limited to the liquid crystaldisplay, and may be display means other than the liquid crystal display(e.g., an organic EL display or a plasma display).

The receiving device 105 is a device, connected to a telephone line orthe Internet, which receives image data from an external apparatus byfacsimile communication. Further, the transmitting device 106 is adevice, connected to a telephone line or the Internet, which transmits,to an external apparatus by facsimile communication, image data inputtedto the image input apparatus 101.

The storage device 107 is a hard disk in which image data to beprocessed in the image processing apparatus 102 is temporarily stored.

The control section 108 is a computer including a processor such as aCPU (central processing unit) or a DSP (digital signal processor), andcomprehensively controls various types of hardware provided in the imageforming apparatus 100. Further, the control section 108 functions tocontrol data transfer between pieces of hardware provided in the imageforming apparatus 100.

The following details the processes that are executed by the blocks ofthe image processing apparatus 102 in the copier mode, the facsimiletransmission mode, the facsimile reception mode, and the imagetransmission mode, respectively. It should be noted that the imageprocessing apparatus 102 of the present embodiment has a block thatoperates while a mode a is being used but does not operate while a modeb different from the mode a is being used (the mode a and the mode beach being any one of the copier mode, the facsimile transmission mode,the facsimile reception mode, and the image transmission mode). Further,the image processing apparatus 102 has a block that varies in processingaccording to the mode being used. Furthermore, the image processingapparatus 102 has: a block that, even in the same mode, operates inprocessing of image data to be printed (transmitted) but does notoperate in processing of image data to be previewed; and a block that,even in the same mode, varies between processing of image data to beprinted (transmitted) and processing of image data to be previewed. Inthe following, therefore, the processes that are executed by the blocksof the image processing apparatus 102 are described according to thetype of mode, and those processes which are executed in a printingprocess (or in a transmission process) and those processes which areexecuted at the time of a preview display are described separately.

1) Copier Mode

(1-1) Printing Process (Image Print Job)

In the following, the image processing apparatus 102 is described withreference to FIG. 1, which shows the flow of image data in the imageprocessing apparatus 102 performing a printing process in the copiermode and the full-color mode.

The A/D (analog/digital) conversion section 2 is a block that receivescolor image signals (RGB analog signals) from the image input apparatus101 and converts the color image signals into digital image data (RGBdigital signals). The shading correction section 3 is a block thatreceives image data form the A/D conversion section 2 and subjects theimage data to a process of removing various distortions generated inilluminating, image-focusing, and image-sensing systems of the imageinput apparatus 101. The input processing section 4 is a block thatreceives RGB image data from the shading correction section 3 andsubjects each of the RGB image data to a tone conversion process such asa gamma correction process.

In accordance with RGB image data (RGB density signals) subjected toprocessing such as gamma correction in the input processing section 4,the automatic document type discrimination section 5 discriminates amongtypes of documents scanned by the image input apparatus 101. It shouldbe noted here that the types of documents among which the automaticdocument type discrimination section 5 discriminates are a textdocument, a printed-picture document, a text/printed-picture documentcontaining a text and a printed picture together, and the like. Further,in accordance with the image data, the automatic document typediscrimination section 5 can perform auto color selection (ACS) forjudging whether a scanned document is a color document or ablack-and-white document and a process for judging whether or not ascanned document is a blank document (a solid-color document). It shouldbe noted that the automatic document type discrimination section 5 sendsthe RGB image data to the segmentation process section 6 and thecompression section 7.

In accordance with the RGB image data sent from the automatic documenttype discrimination section 5, the segmentation process section 6performs a process of judging, for each pixel of the input image, whatimage area the pixel is classified into and generating a segmentationclass signal indicating a result of the judgment. It should be notedhere that the types of image areas among which the segmentation processsection 6 discriminates are a black text area, a color text area, ahalftone dot area, and the like. The segmentation process may take theform of a process of judging, for each block of pixels, what image areathe block is classified into, instead of taking the form of a process ofjudging, for each pixel, what image area the pixel is classified into.

The compression section 7 is a block that performs a process of encodingimage data (RGB signals) sent from the automatic document typediscrimination section 5. The encoding is performed, for example, basedon JPEG (Joint Photographic Experts Group).

The segmentation class signal compression section 8 is a block thatperforms a compression (encode) process on a segmentation class signalgenerated for each pixel. The compression process in the segmentationclass signal compression section 8 is performed, for example, based onMMR (Modified Modified Reed) or MR (Modified Reed), which is a losslesscompression technology.

The control section 108 receives encoded codes (encoded image data) fromthe compression section 7 and segmentation class signal codes (encodedsegmentation class signals) from the segmentation class signalcompression section 8, stores them temporarily in the storage device107, and manages them as filing data. Then, in response to aninstruction for a copy output operation, the control section 108 readsout, from the storage device 107, an encoded code and a segmentationclass signal code corresponding to the encoded code, and sends them tothe decompression section 9 and the segmentation class signaldecompression section 10, respectively.

The control section 108 writes the storage address or data name of theencoded code and the storage address of the segmentation class signalcode in a management table in association with each other. That is, thecontrol section 108 controls reading or writing of encoded codes andsegmentation class signal codes with reference to the management table.

The decompression section 9 decompresses the encoded code into RGB imagedata by performing a decompression (decode) process on the encoded code.Further, the segmentation class signal decompression section 10 performsa decompression process on the segmentation class signal code. Theresulting segmentation class signal is sent to the black generation andunder color removal section 14, the spatial filter section 15, and thehalftone generation section 18. Then, the black generation and undercolor removal section 14, the spatial filter section 15, and thehalftone generation section 18 select image processing according to thetype of image area.

The image-quality adjustment section 11 receives the RGB image data fromthe decompression section 9, and performs background removal correctionon the RGB image data by detecting a background in the RGB image data.Furthermore, the image-quality adjustment section 11 adjusts RGB balance(color adjustment of red, green, or blue), brightness, and intensity(saturation) in accordance with configuration information inputted bythe user from the operation panel (not shown).

Furthermore, in the single-color mode, the image-quality adjustmentsection 11 converts the RGB image data into CMY image data complementaryto the RGB image data. It should be noted here that the conversion ofthe RGB data into the CMY image data in the single-color mode isexecuted by using Eq. (1) below, where the coefficients r1 to r3 aredefined based on [Table 1]. For example, in cases where the user selectscyan as his/her desired color in the single-color mode, the values of r1to r3 in the column “Cyan” are referred to, with the result that r1=1,r2=0, and r3=0 are selected.

$\begin{matrix}{{\begin{pmatrix}C \\M \\Y\end{pmatrix} = {{\begin{pmatrix}{r\;{1 \cdot a}\; 1} & {r\;{1 \cdot a}\; 2} & {r\;{1 \cdot a}\; 3} \\{r\;{2 \cdot a}\; 1} & {r\;{2 \cdot a}\; 2} & {r\;{2 \cdot a}\; 3} \\{r\;{3 \cdot a}\; 1} & {r\;{3 \cdot a}\; 2} & {r\;{3 \cdot a}\; 3}\end{pmatrix} \times \begin{pmatrix}R \\G \\B\end{pmatrix}} + \begin{pmatrix}{r\;{1 \cdot c}} \\{r\;{2 \cdot c}} \\{r\;{3 \cdot c}}\end{pmatrix}}}{{a\; 1} = {- 0.23046875}}{{a\; 2} = {- 0.79296875}}{{a\; 3} = 0.0234375}{c = 255}} & {{Eq}.\mspace{14mu}(1)}\end{matrix}$

TABLE 1 Adjustment Output Color (Single Color) Plane Red Green Blue CyanMagenta Yellow r1 0 1 1 1 0 0 r2 1 0 1 0 1 0 r3 1 1 0 0 0 1

That is, whereas the output from the image-quality adjustment section 11in the full-color mode is RGB image data as shown in FIG. 1, the outputfrom the image-quality adjustment section 11 in the single-color mode isCMY image data as shown in (a) of FIG. 2. It should be noted that theoutput from the image-quality adjustment section 11 in the two-colormode is RGB image data as shown in (b) of FIG. 2. (a) of FIG. 2 showssome of the blocks of the image processing apparatus 102 performing aprinting process in the copier mode and the single-color mode, and (b)of FIG. 2 shows some of the blocks of the image processing apparatus 102performing a printing process in the copier mode and the two-color mode.

Further, the adjustment of intensity by the image-quality adjustmentsection 11 can be realized by using the matrix of Eq. (1) after varyingthe values of r1 to r3 and a1 to a3 of the matrix. This makes itpossible to use the same matrix and the same image processing circuitfor the adjustment of intensity and the conversion of image data (fromRGB into CMY) in the single-color mode. Therefore, in the presentembodiment, the adjustment of intensity and the conversion of image datain the single-color mode are performed by the same processing section(image-quality adjustment section 11).

The two-color printing process section 12 is a block that, in the twocolor mode, receives RGB image data from the image-quality adjustmentsection 11 and converts the RGB image into CMY image data as shown in(b) of FIG. 2. The conversion of the RGB image data into the CMY imagedata in the two-color mode can be realized, for example, by a techniqueof [Embodiment 1] or [Embodiment 2] described in Japanese PatentApplication Publication, Tokukai, No. 2007-28336 A.

Further, in the full-color mode, as shown in FIG. 1, the two-colorprinting process section 12 performs no processing on the image datasent from the image-quality adjustment section 11 and passes the imagedata directly on to the color correction section 13. Furthermore, in thesingle-color mode, as shown in (a) of FIG. 2, two-color printing processsection 12 performs no processing on the CMY image data sent from theimage-quality adjustment section 11 and passes the image data directlyon to the color correction section 13.

The color correction section 13 is a block that, in the full-color mode,receives RGB image data from the two-color printing process section 12,performs a color correction process of converting the RGB image datainto CMY image data, and performs a process of improving the colorreproducibility of the image data. The color correction process isrealized by creating an LUT (look-up table) of input values (RGB) andoutput values (CMY) associated with one another and looking up theoutput values in the created LUT.

Further, in the single-color mode or two-color mode, as shown in FIG. 2,the color correction section 13 performs no processing on the CMY imagedata sent from the two-color printing process section 12 and passes theimage data directly on to the black generation and under color removalsection 14.

The black generation and under color removal section 14 is a block that,in the full-color mode or two-color mode, receives CMY image data fromthe color correction section 13, generates black (K) image data from theCMY image data, and generate new CMY image data by subtracting the black(K) image data from the original CMY image data. Thus, in the full-colormode or two-color mode, as shown in FIG. 1 or (b) of FIG. 2, the blackgeneration and under color removal section 14 converts the CMY imagedata into four colors of image data CMYK.

Further, in the single-color mode, as shown in (a) of FIG. 2, the blackgeneration and under color removal section 14 performs no processing onthe CMY image data sent from the color correction section 13 and passesthe image data directly on to the subsequent spatial filter section 15.

In the full-color mode or two-color mode, the output from the blackgeneration and under color removal section 14 and the input to andoutput from each block subsequent to the black generation and undercolor removal section 14 are CMYK image data as shown in FIG. 1.Meanwhile, in the single-color mode, the output from the blackgeneration and under color removal section 14 and the input to andoutput from each block subsequent to the black generation and undercolor removal section 14 are CMY image data unlike in FIG. 1.

The spatial filter section 15 receives the CMYK or CMY image data fromthe black generation and under color removal section 14 and performs aspatial filter process (e.g., edge enhancement process, smoothingprocess) on the image data by a digital filter in accordance with thesegmentation class signals. That is, the spatial filter section 15executes image processing differently for each image area in accordancewith the segmentation class signals.

The enlarging/reducing section 16 is a block that enlarges or reduces animage in accordance with an enlarging/reducing command (informationindicating the zoom ratio of a printed image) inputted by the user fromthe operation panel (not shown).

The output tone correction section 17 is a block that receives imagedata from the enlarging/reducing section 16 and performs output gammacorrection for outputting the image data onto a recording medium such asa sheet of paper. The halftone generation section 18 executes, bydithering or error diffusion, a tone reproduction process (halftonegeneration process) necessary for the image output apparatus 103 toprint an image.

Then, the halftone generation section 18 passes the CMYK or CMY imagedata on to the image output apparatus 103, and the image outputapparatus 103 prints an image of the image data onto a recording medium(e.g., a sheet of paper).

(1-2) Preview Display

Next, the processes that are executed by the blocks of the imageprocessing apparatus 102 in cases where a preview of an image to beprinted is displayed in the copier mode are described with reference toFIG. 3. FIG. 3 is a block diagram showing the same image formingapparatus 100 as in FIG. 1 and showing the flow of image data at thetime of a preview display process in the copier mode and the full-colormode.

It should be noted that because the A/D (analog/digital) conversionsection 2, the shading correction section 3, the input processingsection 4, the automatic document type discrimination section 5, thesegmentation process section 6, the compression section 7, thesegmentation class signal compression section 8, the decompressionsection 9, the image-quality adjustment section 11, and the two-colorprinting process section 12 perform the same processes as in the case ofa printing process, such processes will not be described below.

At the time of a preview display, as shown in FIG. 3, the segmentationclass signal decompression section 10 decompresses (decodes)segmentation class signals and passes them on to the spatial filtersection 15 and the output tone correction section 17.

In the full-color mode, the color correction section 13 receives RGBimage data in color space of the scanner (image input apparatus 101).Then, the color correction section 13 converts the RGB image data intoR′G′B′ image data in color space of the image display device 104.

That is, the color correction section 13 converts the RGB image data,which conform to the image scanning characteristics of the scanner, intothe R′G′B′ image data, which conform to the display characteristics ofthe display device. It should be noted that the conversion of the RGBimage data into the R′G′B′ image data is also realized by creating anLUT (look-up table) of input values (RGB) and output values (R′G′B′)associated with one another and looking up the output values in thecreated LUT.

Moreover, in the full-color mode, the present embodiment uses the sameimage processing circuit for the conversion of RGB image data into CMYKimage data at the time of a printing process and the conversion of RGBimage data into R′G′B′ image data at the time of a preview display.

As with FIG. 1, FIG. 3 shows the image forming apparatus 100 in thefull-color mode. In the full-color mode, the color correction section 13receives RGB image data. Meanwhile, in the single-color mode ortwo-color mode, as shown in FIG. 4, the color correction section 13receives CMY image data. (a) of FIG. 4 shows some blocks of the imageprocessing apparatus 2 performing a preview display in the copier modeand the singe-color mode, and (b) of FIG. 4 shows some blocks of theimage processing apparatus performing a preview display in the copiermode and the two-color mode.

Then, in the single-color mode or two-color mode, the color correctionsection 13 converts the CMY image data into R′G′B′ image data. That is,the color correction section 13 converts the CMY image data, whichconform to the printing characteristics of the printing process, intothe R′G′B′ image data, which conform to the display characteristics ofthe display device. It should be noted that the conversion of the CMYimage data into the R′G′B′ image data is also realized by creating anLUT (look-up table) of input values (RGB) and output values (R′G′B′)associated with one another and looking up the output values in thecreated LUT.

In any one of the single-color mode, the two-color mode, and thefull-color mode, as shown in FIGS. 3 and 4, the black generation andunder color removal section 14 performs no processing on the R′G′B′image data sent from the color correction section 13 and passes theimage data directly on to the subsequent spatial filter section 15.

The spatial filter section 15 receives the R′G′B′ image data from theblack generation and under color removal section 14 and performs aspatial filter process (e.g., edge enhancement process, smoothingprocess) on the image data by a digital filter in accordance with thesegmentation class signals. That is, as in the case of a printingprocess, the spatial filter section 15 executes image processingdifferently for each image area in accordance with the segmentationclass signals.

The enlarging/reducing section 16 performs a downsampling process bywhich the number of pixels of an image composed of the R′G′B′ image datasent from the spatial filter section 15 is converted into the number ofpixels of the image display device 104 (process by which the number ofpixels is reduced). The image display device 104, provided in theoperation panel of the image forming apparatus 100, is lower inresolution than image data to be printed and, usually, is an extremelysmall display. Therefore, at the time of a preview display, it isnecessary to downsample the image data. Further, the enlarging/reducingsection 16 enlarges or reduces the image in accordance with anenlarging/reducing command (information indicating the zoom ratio of adisplay, e.g., a fixed zoom ratio of 2 to 4 times) inputted from theoperation panel (not illustrated) provided in the image formingapparatus.

The output tone correction section 17 receives the image data from theenlarging/reducing section 16 and performs output gamma correction onthe image data in accordance with the segmentation class signals. Morespecifically, in accordance with the segmentation class signals, theoutput tone correction section 17 selects different gamma curves fordifferent image areas and varies in output gamma correction from oneimage area to another. For example, for nontext areas, the output tonecorrection section 17 selects a gamma curve corresponding to the displaycharacteristics of the image display device 104, and for text areas,selects a gamma curve for texts to be sharply displayed. (a) of FIG. 5shows a gamma curve corresponding to the display characteristics of theimage display device 104, and (b) of FIG. 5 shows a solid linerepresenting a gamma curve for texts to be sharply displayed and adotted line representing a gamma curve corresponding to the displaycharacteristics of the image display device 14. The dotted line is shownfor comparison with the gamma curve for texts to be sharply displayed.

In the present embodiment, the output tone correction section 17 selectsbetween the gamma curves in accordance with the segmentation classsignals. However, the output tone correction section 17 may performoutput tone correction by using only the gamma curve of (a) of FIG. 5,instead of making selection in accordance with the segmentation classsignals.

Then, the halftone generation section 18 performs no processing on theR′G′B′ image data sent from the output tone correction section 17 andpasses the image data directly on to the subsequent image display device104. This allows the image display device 104 to display, in accordancewith the R′G′B′ image data, a preview of an image to be copied.

It should be noted that in place of the output tone correction section17, the image-quality adjustment section 11 may execute output gammacorrection.

(1-3) As to Whether the Blocks Operate or Do Not Operate

As described above, at the time of printing in the full-color mode, theimage-quality adjustment section 11 through the halftone generationsection 18 all operate except for the two-color printing process section12 (see FIG. 1). Meanwhile, at the time of a preview display in thefull-color mode, the image-quality adjustment section 11 through thehalftone generation section 18 all operate except for the two-colorprinting process section 12, the black generation and under colorremoval section 14, and the halftone generation section 18 (see FIG. 3).

Further, at the time of printing in the two-color mode, theimage-quality adjustment section 11 through the halftone generationsection 18 all operate except for the color correction section 13 (see(b) of FIG. 2). Meanwhile, at the time of a preview display in thetwo-color mode, the image-quality adjustment section 11 through thehalftone generation section 18 all operate except for the blackgeneration and under color removal section 14 and the halftonegeneration section 18 (see (b) of FIG. 4).

Furthermore, at the time of printing in the single-color mode, theimage-quality adjustment section 11 through the halftone generationsection 18 all operate except for the two-color printing process section12, the color correction section 13, and the black generation and undercolor removal section 14 (see (a) of FIG. 2). Meanwhile, at the time ofa preview display in the single-color mode, the image-quality adjustmentsection 11 through the halftone generation section 18 all operate exceptfor the two-color printing process section 12, the black generation andunder color removal section 14, and the halftone generation section 18(see (a) of FIG. 4).

(1-4) Steps of a Process

Next, an example of steps of a process in the copier mode and thefull-color mode is described with reference to FIG. 6. FIG. 6 is a flowchart showing an example of steps of a process that is performed by theimage forming apparatus in the copier mode and the full-color mode.

In response to a pressing of a start key (YES in S1) in the copier mode,the image forming apparatus 100 generates RGB analog signals by scanninga document (S2). It is assumed here that prior to the pressing of thestart key in S1, the user inputs setting information indicating whetheror not a preview display is necessary and thereby sets whether or notthe image forming apparatus 100 performs a preview display.

After S2, the image forming apparatus 100 converts the RGB analogsignals into RGB image data (digital data) (S3), subjects the RGB imagedata to shading correction (S4), and then subjects the RGB image data toinput gamma correction (S5). After S5, the image forming apparatus 100performs a document type discrimination process and a segmentationprocess in accordance with the RGB image data (S6), and then stores theRGB image in the storage device 107 (S7).

After S7, the image forming apparatus 100 judges whether or not it hasbeen set to “Preview Display: Yes” (S8). In cases where it has not beenset to “Preview Display: Yes”, the image forming apparatus 100 executesSteps S9 through S16. In cases where it has been set to “PreviewDisplay: Yes”, the image forming apparatus 100 executes Steps S17through S23. In the following, Steps S9 through S16 are described first,and then Steps S17 through S23 are described.

In cases where the image forming apparatus 100 has not been set to“Preview Display: Yes” (NO in S8), the image forming apparatus 100 readsout the RGB image data from the storage device 107, and then performs animage-quality adjustment process such as background removal correctionand adjustment of intensity (S9). After that, the image formingapparatus 100 converts the RGB image data, which conforms to thecharacteristics of the scanner, into CMY image data conforming to thecharacteristics of the printer (S10), and then converts the CMY imagedata into CMYK image data (S11). After that, the image forming apparatus100 performs a spatial filter process on the CMYK image data inaccordance with a result of the segmentation process (S12), and thenperforms an enlarging/reducing process on the CMYK image data (S13).After S13, the image forming apparatus 100 performs output gammacorrection and a tone reproduction process on the CMYK image data (S14,S15), prints an image of the image data on a sheet of paper (S16), andthen finishes the process.

In cases where the image forming apparatus 100 judges, in S8, that ithas been set to “Preview Display: Yes” (YES in S8), the image formingapparatus 100 reads out the RGB image data from the storage device 107,and then performs the same image-quality adjustment process as in S9(S17). After that, the image forming apparatus 100 converts the RGBimage data, which conforms to the characteristics of the scanner, intoR′G′B′ image data conforming to the characteristics of the displaydevice (S18). After S18, the image forming apparatus 100 performs aspatial filter process on the R′G′B′ image data in accordance with aresult of the segmentation process (S19), and then performs adownsampling process on the R′G′B′ image data so that the R′G′B′ imagedata conforms to the resolution and size of the display (S20). AfterS20, the image forming apparatus 100 performs output gamma correction onthe R′G′B′ image data in accordance with the result of the segmentationprocess (S21). After S21, the image forming apparatus 100 performs apreview display in accordance with the R′G′B′ image data (S22). Then,after S22, upon receiving, from the user, a command indicatingpermission of printing (YES in S23), the image forming apparatus 100again reads out the RGB image data from the storage device 107, and thenperforms printing by executing Steps S9 through S16 in accordance withthe image data. On the other hand, after S22, upon receiving, from theuser, a command indicating cancellation of printing (NO in S23), theimage forming apparatus 100 finishes the process.

2) Facsimile Transmission Mode

(2-1) Transmission Process (Image Transmission Job)

FIG. 7 is a block diagram showing the same image forming apparatus 100as in FIG. 1 and showing the flow of image data in a transmissionprocess in the facsimile transmission mode. It should be noted thatbecause the A/D (analog/digital) conversion section 2, the shadingprocess section 3, the input processing section 4, the automaticdocument type discrimination section 5, the segmentation process section6, the compression section 7, the segmentation class signal compressionsection 8, and the decompression section 9 performs the same processesas in the case of the copier mode, such processes will not be describedbelow.

In the facsimile transmission mode, the segmentation class signaldecompression section 10 reads out the segmentation class signal codesfrom the storage device 107, decompresses the segmentation class signalcodes, and then transmits the decompressed (decoded) segmentation classsignal codes to the spatial filter section 15.

The image-quality adjustment section 11 receives the RGB image data fromthe decompression section 9 and converts the RGB image into K image data(a value indicating grayscale). It should be noted that this conversionis performed by using a predetermined matrix of coefficients and Eq. (2)below:Luminance(Value of K Image Data)=0.299r+0.587g+0.114b  Eq. (2)where r is the value (density) of red image data, g is the value ofgreen image data, and b is the value of blue image data.

The two-color printing process section 12, the color correction section13, and the black generation and under color removal section 14 performno processing on the K image data (signal) sent from the image-qualityadjustment section 11 and pass the K image data directly on to thesubsequent spatial filter section 15.

The spatial filter section 15 performs a spatial filter process (e.g.,edge enhancement process, smoothing process) on the K image data by adigital filter in accordance with the segmentation class signals. Theenlarging/reducing section 16 performs an enlarging/reducing process onthe K image data in accordance with the transmission resolution. Theoutput tone correction section 17 performs output gamma correction(gamma correction for output onto a recording medium such as a sheet ofpaper) on the K image data sent from the enlarging/reducing section 16.The halftone generation section 18 converts the K image data intobinarized image data, for example, by error diffusion. Then, thebinarized image data are rotated by a rotation process section (notshown) as needed, compressed by a compression/decompression section (notshown) into a predetermined form, and then stored in a memory (notshown).

After that, the transmitting device (e.g., modem) 106 performs aprocedure for transmission to the destination and ensurestransmittability to the destination. Then, the transmitting device 106reads out the binarized image data, stored in the memory, with thebinarized image data compressed in the predetermined form, subjects thebinarized image data to necessary processes such as a conversion incompression format, and then transmits the binarized image data insequence via a communication line.

(2-2) Preview Display

FIG. 8 is a block diagram showing the same image forming apparatus 100as in FIG. 1 and showing the flow of image data in a preview displayprocess in the facsimile transmission mode. The term “preview display inthe facsimile transmission mode” here means a process of displaying apreview of an image to be transmitted by facsimile.

At the time of a preview display, the A/D conversion section 2, theshading correction section 3, the input processing section 4, theautomatic document type discrimination section 5, the segmentationprocess section 6. The compression section 7, the segmentation classsignal compression section 8, the decompression section 9, thesegmentation class signal decompression section 10, the image-qualityadjustment section 11, and the spatial filter section 15 perform thesame processes as in the case of a facsimile transmission process;therefore, such processes are not described. Further, as in the case ofa facsimile transmission process, the two-color printing process section12, the color correction section 13, and the black generation and undercolor removal section 14 do not perform any processes.

However, at the time of a preview display, unlike in the case of atransmission process, as shown in FIG. 8, three pieces of K image data(all being equal in value) are transmitted for each pixel all the wayfrom the image-quality adjustment section 11 to the image display device104. This is because the image display device 104 is a full-color modeland as such requires three values (pieces of image data) for one pixel.

The enlarging/reducing section 16 performs a downsampling process on theK image data so that the number of pixels of an image composed of the Kimage data sent from the spatial filter section 15 conforms to thenumber of pixels of the display size of the image display device 104.Further, the enlarging/reducing section 16 enlarges or reduces the imagein accordance with an enlarging/reducing command (information indicationthe zoom ratio of a display, e.g., a fixed zoom ratio of 2 to 4 times)inputted from the operation panel (not shown) provided in the imageforming apparatus 100.

The output tone correction section 17 receives the K image data from theenlarging/reducing section 16 and performs gamma correction on the Kimage data in conformity to the display characteristics of the imagedisplay device 104. Then, the halftone generation section 18 performs noprocessing on the K image data sent from the output tone correctionsection 17 and passes the K image data directly on to the subsequenceimage display device 104. This allows the image display device 104 todisplay, in accordance with the K image data, a preview of an image tobe transmitted by facsimile.

Further, at the time of a preview display process in the facsimiletransmission mode, the image-quality adjustment section 11 converts theRGB image data into three pieces of K image data. However, there is nosuch limitation in embodiment. For example, it is possible to performimage processing without converting RGB image data into K image data upto the output tone correction section 17, to receive the RGB image datafrom the output tone correction section 17, and to convert the RGB imagedata into K image data by a browser.

(2-3) As to Whether the Blocks Operate or Do Not Operate

As described above, at the time of a transmission process in thefacsimile transmission mode, the image-quality adjustment section 11through the halftone generation section 18 all operate except for thetwo-color printing process section 12, the color correction section 13,and the black generation and under color removal section 14 (see FIG.7). Meanwhile, at the time of a preview display in the facsimiletransmission mode, the image-quality adjustment section 11 through thehalftone generation section 18 all operate except for the two-colorprinting process section 12, the color correction section 13, the blackgeneration and under color removal section 14, and the halftonegeneration section 18 (see FIG. 8).

(2-4) Steps of a Process

Next, an example of steps of a process in the facsimile transmissionmode is described. In cases where the image forming apparatus 100receives a fax transmission command from the user with the image formingapparatus 100 having not been set to “Preview Display: Yes”, the imageforming apparatus 100 processes image data as shown in FIG. 7 andtransmits the image data to an external apparatus.

Meanwhile, in cases where the image forming apparatus 100 receives a faxtransmission command from the user with the image forming apparatus 100set to “Preview Display: Yes”, the image forming apparatus 100 processesimage data as shown in FIG. 8, thereby storing the image data in thestorage device 107 and displaying a preview of an image of the imagedata on the image display device 104. Then, when the image formingapparatus 100 receives a transmission permission command from the userwith the preview being displayed, the image forming apparatus 100 readsout the image data from the storage device 107, processes the image datain the decompression section 9 through the halftone generation section18 as shown in FIG. 7, and transmits the image data to an externalapparatus via the transmitting device 106.

3) Facsimile Reception Mode

(3-1) Printing Process (Image Print Job)

FIG. 9 is a block diagram showing the same image forming apparatus 100as in FIG. 1 and showing the flow of image data in a printing process inthe facsimile reception mode.

In the case of facsimile reception, the receiving device 105 receives Kimage data (1 bit) from the source while performing a communicationprocedure. Then, the K image data received by the receiving device 105are decompressed by the compression/decompression section (not shown),rotated by the rotation process section (not shown) as needed, and thensubjected to a resolution conversion process by a resolution conversionsection (not shown). After that, the image data are stored temporarilyin the storage device 107.

Furthermore, the image data written in the storage device 107 are passedon to the decompression section 9 of the image processing apparatus 102by the control section 108. The decompression section 9, theimage-quality adjustment section 11, the two-color printing processsection 12, the color correction section 13, the black generation andunder color removal section 14, the spatial filter section 15, theenlarging/reducing section 16, the output tone correction section 17,and the halftone generation section 18 perform no processing on theimage data sent from the storage device 107 and pass the image datadirectly onto the subsequent image output apparatus 103. The imageoutput apparatus 103 forms an image on a recording medium (e.g., a sheetof paper) in accordance with the K image data sent from the halftonegeneration section 18. In the case of a printing process in thefacsimile reception mode, image processing is not performed as describedabove. Therefore, the image data stored in the storage device 107 may beoutputted directly to the image output apparatus 103.

(3-2) Preview Display

FIG. 10 is a block diagram showing the same image forming apparatus 100as in FIG. 1 and showing the flow of image data in a preview displayprocess in the facsimile reception mode. The term “preview display inthe facsimile reception mode” here means a process of, before printingan image of image data received by facsimile, displaying a preview ofthe image to be printed.

Also at the time of a preview display in the facsimile reception mode,as in the case of a printing process in the facsimile reception mode,the image data written in the storage device 107 are passed on to thedecompression section 9 of the image processing apparatus 102 by thecontrol section 108. The decompression section 9 performs no processingon the image data sent from the storage device 107 and passes the imagedata on to a bit-number conversion process section (not shown). Then,the bit-number conversion process section converts the number of bits ofthe image data sent from the decompression section 9 (e.g., from 1 bitto 8 bits), and then passes the image data on to the image-qualityadjustment section 11. That is, although not shown in FIG. 10, thedecompression section 9 and the image-quality adjustment section 11 hasthe bit-number conversion section provided therebetween.

As shown in FIG. 10, for each pixel, the image-quality adjustmentsection 11 receives one piece of K image data and generates and outputsthree pieces of K image data (all being equal in value). This is becausethe image display device 104 is a full-color model and as such requiresthree values for one pixel.

After that, the two-color printing process section 12, the colorcorrection section 13, and the black generation and under color removalsection 14 perform no processing on the K image data sent from theimage-quality adjustment section 11 and pass the image data directly onthe subsequent spatial filter section 15. The spatial filter section 15performs a blur (smoothing) process and the like on the K image datawith use of a digital filter.

The enlarging/reducing section 16 performs a downsampling process on theK image data so that the number of pixels of an image of the K imagedata sent from the spatial filter section 15 conforms to the number ofpixels of the display size of the image display device 104. Further, theenlarging/reducing section 16 enlarges or reduces the image inaccordance with an enlarging/reducing command (information indicationthe zoom ratio of a display, e.g., a fixed zoom ratio of 2 to 4 times)inputted from the operation panel (not shown) provided in the imageforming apparatus 100.

The output tone correction section 17 receives the K image data from theenlarging/reducing section 16 and performs output gamma correction onthe K image data in conformity to the display characteristics of theimage display device 104. Then, the halftone generation section 18performs no processing on the K image data sent from the output tonecorrection section 17 and passes the K image data directly on to thesubsequence image display device 104. This allows the image displaydevice 104 to display, in accordance with the K image data, a preview ofan image received by facsimile.

(3-3) As to Whether the Blocks Operate or Do Not Operate

As described above, at the time of a printing process in the facsimilereception mode, the image-quality adjustment section 11 through thehalftone generation section 18 do not operate (see FIG. 9). Meanwhile,at the time of a preview display in the facsimile reception mode, theimage-quality adjustment section 11 through the halftone generationsection 18 all operate except the two-color printing process section 12,the color correction section 13, the black generation and under colorremoval section 14, and the halftone generation section 18 (see FIG.10).

(3-4) Steps of a Process

Next, an example of steps of a process in the facsimile reception modeis described. In cases where the image forming apparatus 100 receivesimage data by facsimile, the received image data are written temporarilyin the storage device 107. It should be noted here that there is a timelag between the writing of the image data in the storage device 107 andprinting of an image. In cases where the user inputs a “preview command”during the time lag, the image data is processed along such a flow asshown in FIG. 10, and a preview of an image of the image data isdisplayed by the image display device 104. Further, when the image isprinted, the image data is processed along such a flow as shown in FIG.9, and the image of the image data is printed by the image outputapparatus 103.

4) Image Transmission Mode

(4-1) Transmission Process (Image Transmission Job)

In the case of operation of the image forming apparatus 100 at the timeof a transmission process in the image transmission mode, the imageinput apparatus 101, the A/D (analog/digital) conversion section 2, theshading correction section 3, the input processing section 4, theautomatic document type discrimination section 5, the segmentationprocess section 6, the compression section 7, the segmentation classsignal compression section 8, and the decompression section 9 performsthe same processes as in the case of the copier mode. It should be notedthat the segmentation class signal decompression section 10 supplies thesegmentation class signals to the spatial filter section 15 and theoutput tone correction section 17.

Then, the image-quality adjustment section 11 performs a backgroundremoval process and color balance adjustment. The color correctionsection 13 converts the image data into R″G″B″ image data (e.g., sRGBdata) conforming to the display characteristics of a commonly-useddisplay device. The spatial filter section 15 performs a spatial filterprocess (edge enhancement process, smoothing process) by a digitalfilter in accordance with the segmentation class signals. Theenlarging/reducing section 16 enlarges or reduces the image. Further,the output tone correction section 17 performs correction on a text areawith use of the gamma curve of (b) of FIG. 5, and performs correction ona nontext area with use the gamma curve of (a) of FIG. 5, for example.The two-color printing process section 12 and the black generation andunder color removal section 14 perform no processing on the input imagedata, and each of the blocks passes the image data directly on to thesubsequent block. Therefore, the output tone correction section 17outputs the R″G″B″ image data.

Furthermore, the R″G″B″ image data from the output tone correctionsection 17 are converted into an image file such as a PDF file by aformat conversion process section (not shown). Then, in the scan toe-mail mode, which is an image transmission mode, the image file isattached to an e-mail by the mail processing section (job apparatus; notshown), and the e-mail is transmitted to the destination via a network.Alternatively, in the scan to ftp mode, which is another imagetransmission mode, the image file is transmitted to a predeterminedfolder. Alternatively, in the scan to usb mode, which is the other imagetransmission mode, the image file is transmitted to a predetermined USBmemory.

(4-2) Preview Display

In the case of operation of the image forming apparatus 100 at the timeof a preview display in the image transmission mode, the image inputapparatus 101, the A/D (analog/digital) conversion section 2, theshading correction section 3, the input processing section 4, theautomatic document type discrimination section 5, the segmentationprocess section 6, the compression section 7, the segmentation classsignal compression section 8, the decompression section 9, thesegmentation class signal decompression section 10, the image-qualityadjustment section 11, and the two-color printing process section 12perform the same processes as in the case of transmission in the imagetransmission mode.

Then, at the time of a preview display in the image transmission mode,the color correction section 13 converts the RGB image data into R′G′B′image data conforming to the color space of the image display device104.

After that, as in the case of transmission, the spatial filter section15 performs a spatial filter process (edge enhancement process,smoothing process) by a digital filter in accordance with thesegmentation class signals. The enlarging/reducing section 16 performs adownsampling process for a match in size for the image display device104. Further, the output tone correction section 17 performs correctionon a text area with use of the gamma curve of (b) of FIG. 5, andperforms correction on a nontext area with use the gamma curve of (a) ofFIG. 5, for example.

Then, the output tone correction section 17 supplies the R′G′B′ imagedata to the image display device 104, and the image display device 104performs a preview display in accordance with the R′G′B′ image data.

(5) Modification

In the image forming apparatus 100 of FIG. 1, the compressed image data(encoded codes) and the segmentation class signal codes are stored inthe storage device 107 in association with one another. However, as inan image forming apparatus 100 a of FIG. 11, there may be such anarrangement that: after the image input apparatus 101 reads image data,the image data are encoded and stored temporarily in the storage device107 before a segmentation process and an automatic document typediscrimination process; and the image data are read out from the storagedevice 107, decompressed, and then subjected to a segmentation processand an automatic document type discrimination process.

Further, the image forming apparatus 100 of FIG. 1 may be capable ofexecuting an image filing mode (image filing job) during a job such asthe copier mode, the printer mode, the facsimile transmission mode, thefacsimile reception mode, or the image transmission mode. The imagefiling mode is a mode in which to create an image file (e.g., JPEG orTIFF file), during a job such as the copier mode, in accordance withimage data obtained by the image input apparatus 101 or image datareceived from outside and store the image file in the storage device107.

At the time of filing in the image filing mode, the image data obtainedby the image input apparatus 101 or the image data received from outsideare converted into an image file (e.g., JPEG or TIFF file) by the imageprocessing apparatus 102. The image filed is sent to a filing processingsection (job apparatus; not shown). The filing processing section storesthe image file in the storage device 107.

Further, in the case of a preview during each job (e.g., the copiermode, the print mode, or the facsimile transmission mode), the imagedata obtained by the image input apparatus 101 or the image datareceived from outside are processed by the image processing apparatus102, and then sent to the image display device 104, regardless of theexecution of the image filing mode. Furthermore, in the case of apreview during each job, the image processing apparatus 102 executes thesame image processing regardless of the execution of the image filingmode. For example, at the time of a preview display in the copier mode,the image processing apparatus 102 performs such processes as shown inFIG. 3, regardless of the execution of the image filing mode. Further,at the time of a preview display in the facsimile transmission mode, theimage processing apparatus 102 performs such processes as shown in FIG.8, regardless of the execution of the image filing mode.

(6) Advantages of the Image Processing Apparatus of the PresentEmbodiment

The image processing apparatus 102 of the present embodiment suppliesimage data to the image output apparatus (job apparatus, printingapparatus) 103, which performs a print job (copier mode, print mode),and supplies the image data to the image display device 104 so that theimage display device 104 displays a preview before the execution of theprint job.

Moreover, the image processing apparatus 102 includes a first imageprocessing section which performs first image processing on image datato be supplied to the image output apparatus 103, which performs secondimage processing on image data to be supplied to the image displaydevice 104, the second image processing being different from the firstimage processing, and which performs the first image processing and thesecond image processing with use of a common circuit area. An example ofthe first image processing section is the color correction section 13 inthe copier mode and the full-color mode. This is because the colorcorrection section 13 uses a common circuit area for a process ofconversion from RGB into CMY (first image processing) and a process ofconversion from RGB into R′G′B′ (second image processing).

This brings about a merit of reducing the circuit size of an imageprocessing circuit even in an image processing apparatus that performsimage processing for a printing process or the like and image processingfor a preview before the printing process.

Further, in the present embodiment, at the time of printing in thecopier mode and the full-color mode, the color correction section 13performs a process by which additive image data (RGB) read by thescanner and conforming to the characteristics of the scanner areconverted into subtractive image data (CMY) conforming to thecharacteristics of the image output apparatus 103. Meanwhile, at thetime of a preview in the copier mode and the full-color mode, the colorcorrection section 13 performs a process by which the additive imagedata (RGB) read by the scanner and conforming to the characteristics ofthe scanner are converted into additive image data (R′G′B′) conformingto the characteristics of the image display device 104. That is, at thetime of a preview display, the additive image data conforming to thecharacteristics of the scanner are converted directly into the imagedata conforming to the characteristics of the image display device 104.Therefore, at the time of a preview display in the copier mode and thefull-color mode, the image processing apparatus 102 of the presentembodiment performs a single nonlinear conversion from the RGB imagedata into the R′G′B′ image data, but does not perform a plurality ofnonlinear conversions as in the arrangement of Japanese PatentApplication Publication, Tokukaihei, 9-135316 A (1997), thus making itpossible to suppress accumulation of errors in conversion and suppressdeterioration in color reproducibility. In Japanese Patent ApplicationPublication, Tokukaihei, 9-135316 A (1997), a total of four conversionsare performed, namely the conversion from RGB data into CMY data, theconversion from CMY data into CMYK data, the conversion from CMYK datainto CMY data, and the conversion from the CMY data into RGB data, whichresult in accumulation of errors in conversion and deterioration incolor reproducibility.

Further, at the time of a preview in the copier mode and thesingle-color mode or at the time of a preview in the copier mode and thetwo-color mode, the present embodiment performs such a nonlinearconversion, but the number of such nonlinear conversions is only two.Therefore, it is possible to better suppress deterioration in colorreproducibility than in the arrangement of Japanese Patent ApplicationPublication, Tokukaihei, 9-135316 A (1997), in which a total of fournonlinear conversions are performed.

Furthermore, in the present embodiment, at the time of printing in thecopier mode and the full-color mode, the black generation and undercolor removal section 14 converts CMY image into CMYK image data;meanwhile, at the time of a preview display in the copier mode and thefull-color mode, the black generation and under color removal section 14performs no processing on R′G′B′ and outputs R′G′B′ directly. This makesit possible to simplify the circuit arrangement by using a common imagedata path in the image processing circuit for printing image data thatneeds to be converted from CMY into CMYK and preview image data thatdoes not need to be subjected to a black generation and under colorremoval process.

The image processing apparatus 102 of the present embodiment can performimage processing based on a result of judgment by the automatic documenttype discrimination section 5, image processing based on a result ofprocessing by the segmentation process section 6, and a backgroundremoval process. The effects of these processes are reflected in apreview image that is displayed by the image display device 104.

Embodiment 2

In Embodiment 1, at the time of a preview display in the copier mode,the facsimile transmission mode, or the image transmission mode, thespatial filter section 15 executes different spatial filter processesfor each image area in accordance with the segmentation class signals.Moreover, at the time of a preview display, the spatial filter section15 performs a pixel-downsampling process by which the number of pixelsof image data (image processing data) to be displayed is matched to thenumber of pixels of the image display device 104. Here, in the case of apreview display of an image subjected to a segmentation process, imagedata composed of segmentation class signals cannot be downsampled withinterpolation. This may cause a lack of image information anddeterioration in image quality as a result.

Accordingly, at the time of a preview display, the present embodimentperforms a blur process for blurring image data (image processing data)to be displayed. An example of the blur process is a process, describedbelow, which is performed by the spatial filter section 15 or theenlarging/reducing section 16.

[Spatial Filter Section]

As shown in FIG. 12, the spatial filter section (blur process section)15 includes a filter-coefficient selection section 151, afilter-coefficient storage section 152, and a filter process section153. The filter-coefficient selection section 151 selects filtercoefficients in accordance with an operation mode signal indicative of aprocess such as a printing process, a transmission process, or a previewdisplay process in each of the copier mode, the facsimile transmissionmode, the facsimile reception mode, and the image transmission mode.

The filter-coefficient storage section 152 is a block in which to storefilter coefficients corresponding to operation mode signals. The filterprocess section 153 is a block that executes a filter process on imagedata with use of filter coefficients selected by the filter-coefficientselection section 151.

At the time of a printing process in the copier mode, at the time of atransmission process in the facsimile transmission mode, or at the timeof a transmission process in the image transmission mode, the spatialfilter section 15 receives the segmentation class signals, and thefilter-coefficient selection section 151 therefore selects filtercoefficients in accordance with the received operation mode signal(indicative of the printing process in the copier mode, the transmissionprocess in the facsimile transmission mode, or the transmission processin the image transmission mode) and the segmentation class signals. Atthe time of a printing process in the facsimile reception mode, thespatial filter section 15 receives no segmentation class signals, andthe filter-coefficient selection section 151 therefore selects filtercoefficients in accordance with the operation mode signal indicative ofthe printing process in the facsimile reception mode.

Further, at the time of a preview display in each mode, thefilter-coefficient selection section 151 selects filter coefficients fora blur process on the input image data (image processing data) (i.e.,the R′G′B′ image data in the copier mode or image transmission mode, theK image data in the facsimile transmission mode or facsimile receptionmode). The filter coefficients for the blur process are filtercoefficients for a smoothing process. An example is a matrix of filtercoefficients that become larger than one another toward the center ofthe matrix and become smaller than one another toward the periphery ofthe matrix. A specific example is as follows:

$\quad\begin{pmatrix}0 & 1 & 2 & 1 & 0 \\1 & 3 & 5 & 3 & 1 \\2 & 5 & 10 & 5 & 2 \\1 & 3 & 5 & 3 & 1 \\0 & 1 & 2 & 1 & 0\end{pmatrix}$

The coefficients for the blur process are not limited to those shownabove, and it is preferable to use such coefficients that uniformblurring can be achieved. Further, it is possible to use filtercoefficients all of which take on a value of 1. It should be noted thatit is better not to use a filter having both enhancement and smoothnesscharacteristics.

Furthermore, as shown in FIG. 13, in the facsimile mode (at the time ofa transmission process or a preview display), the filter-coefficientselection section 151 may select filter coefficients in accordance withthe resolution of the image input apparatus 101 (i.e., the resolution atwhich the input image data have been read). Specifically, at higherresolution, the filter-coefficient selection section 151 selectscoefficients lower in degree of blurring.

Examples of resolution include: a resolution of 200×100 dpi for normaltext; a resolution of 200×200 dpi for small text; a fine resolution of200×400 dpi; and a highly fine resolution of 400×400 dpi. Examples offilter coefficients corresponding to these resolutions are as follows.First, a specific example of filter coefficients corresponding to theresolution for normal text is as follows:

$\quad\begin{pmatrix}3 & 7 & 10 & 7 & 3 \\7 & 10 & 15 & 10 & 7 \\10 & 15 & 20 & 15 & 10 \\7 & 10 & 15 & 10 & 7 \\3 & 7 & 10 & 7 & 3\end{pmatrix}$

Further, a specific example of filter coefficients corresponding to theresolution for small text is as follows:

$\quad\begin{pmatrix}0 & 1 & 3 & 1 & 0 \\1 & 5 & 7 & 5 & 1 \\3 & 7 & 15 & 7 & 3 \\1 & 5 & 7 & 5 & 1 \\0 & 1 & 3 & 1 & 0\end{pmatrix}$

Furthermore, a specific example of filter coefficients for the fineresolution is as follows:

$\quad\begin{pmatrix}0 & 0 & 1 & 0 & 0 \\0 & 3 & 5 & 3 & 0 \\1 & 5 & 10 & 5 & 1 \\0 & 3 & 5 & 3 & 0 \\0 & 0 & 1 & 0 & 0\end{pmatrix}$

Further, a specific example of filter coefficients for the highly fineresolution is as follows:

$\quad\begin{pmatrix}0 & 0 & 0 & 0 & 0 \\0 & 1 & 2 & 1 & 0 \\0 & 2 & 4 & 2 & 0 \\0 & 1 & 2 & 1 & 0 \\0 & 0 & 0 & 0 & 0\end{pmatrix}$

In cases where the image input apparatus 101 differs in resolutionbetween a main scanning direction and a sub-scanning direction (e.g.,100×200 dpi and 200×100 dpi), it is possible to set and select differentfilter coefficients.

Such selection of filter coefficients may be made, for example, in thecopier mode (at the time of a printing process or a preview display) orthe image transmission mode (at the time of a transmission process or apreview display), as well as in the facsimile transmission mode.

[Enlarging/Reducing Section]

At the time of a preview display on the image display device 104, theenlarging/reducing section (blur process section) 16 performs adownsampling process (interpolation process) on image data (imageprocessing data) by interpolation in accordance with the resolution andscreen size of the image display device 104. The downsampling processachieves a reduction in data size, thus making it possible to shortenthe amount of time it takes to display image data to be displayed.

As shown in FIG. 14, the enlarging/reducing section 16 includes aninterpolation method selection section 161, a first interpolationprocess section 162, and a second interpolation process section 163.

The interpolation method selection section 161 selects an interpolationmethod for the image data (image processing data) (i.e., the R′G′B′image data in the copier mode or image transmission mode, the K imagedata in the facsimile transmission mode or facsimile reception mode) inaccordance with the operation mode signal.

The first interpolation process section 162 performs an interpolationprocess on the image data with use of a nearest neighbor method, and thesecond interpolation process section 163 performs an interpolationprocess on the image data with use of a bilinear method. The term“nearest neighbor method” here means a method by which the value of anexisting pixel closest to the pixel to be interpolated or in apredetermined position relationship with the pixel to be interpolated istaken as the value of the pixel to be interpolated. Further, the term“bilinear method” here means a method by which the average of valuesweighed in proportion to the distance of four existing pixels around thepixel to be interpolated is taken as the value of the pixel to beinterpolated. The second interpolation process section 163 may use abicubic method (i.e., a method by which interpolation calculation isperformed with use of a total of sixteen pixels, i.e., twelve pixelsaround the pixel to be interpolated and the four pixels around the pixelto be interpolated, in addition to the four pixels around the pixel tobe interpolated), instead of using the bilinear method. Use of thebilinear or bicubic method as a method for interpolating the image dataresults in blurring of the image data, whereby the image data (imageprocessing data) are subjected to a blur process.

When the operation mode signal is a signal indicative of a transmissionprocess in the facsimile transmission mode, the interpolation methodselection section 161 selects the nearest neighbor method as a methodfor interpolating the image data, and then sends the image data to thefirst interpolation process section 162. When the operation mode signalis a signal indicative of a preview display process in the facsimiletransmission mode or a signal indicative of a mode other than thefacsimile transmission mode, the interpolation method selection section161 selects the bilinear or bicubic method as a method for interpolatingthe image data, and then sends the image data to the secondinterpolation process section 163. It should be noted that the bilinearmethod results in a more blurred image than the nearest neighbor methoddoes and the bicubic method results in a slightly more edge-enhancedimage than the bilinear method does.

As described above, the process of blurring image data (image processingdata) whose preview is to be displayed can be performed by the spatialfilter section 15 or the enlarging/reducing section 16. In the case of ablur process through a filter process in the spatial filter section 15at the time of a preview display, the enlarging/reducing section 16 mayperform an interpolation process with use of the nearest neighbormethod. Further, in cases where the enlarging/reducing section 16performs an interpolation process with use of the bilinear or bicubicmethod, the spatial filter section 15 does not need to perform a blurprocess. However, it is preferable that the spatial filter processsection 15 performs a blur process with filter coefficients and theenlarging/reducing section 16 performs an interpolation process with useof the bilinear or bicubic method. That is, although it is possible toperform a blur process only in either the spatial filter section 15 orthe enlarging/reducing section 16, it is preferable to perform blurprocesses both in the spatial filter section 15 and theenlarging/reducing section 16.

The blur process thus performed on image data whose preview is to bedisplayed makes it possible to inhibit deterioration in image qualityeven if the preview is displayed by an image display device whoseresolution is lower than the resolution at which the input image datahave been read. This makes it possible to display a high-quality previewof a text and/or line art image as well as a picture image and therebyenhance the legibility of texts and/or the like. If the image displaydevice 104 has a large screen, it is possible to reduce the degree ofblurring. However, a reduction in degree of blurring leads to anincrease in amount of time before image data to be displayed begin to bedisplayed. Therefore, it is preferable to determine the level ofblurring in consideration of the increase.

The present embodiment can be achieved by storing, in acomputer-readable storage medium containing control program code(executable program, intermediate code program, or source program) to beexecuted by a computer, an image processing method for performing apreview while reducing a lack of image information by performing a blurprocess on the text and/or line art image as well as the picture image.This makes it possible to provide a portable storage medium containing aprogram for the image processing method.

In the present embodiment, the storage medium may be a memory (notshown) for processing in a microcomputer. For example, the storagemedium may be a program medium such as a ROM per se. Alternatively, thestorage medium may be a program medium that can read by inserting thestorage medium into a program reading device provided as an externalstorage device (not shown).

In either case, the contained program code may be arranged to beaccessible to a microprocessor that will execute the program code.Alternatively, the program code may be arranged to be read and thendownloaded to a program storage area (not shown) of the microcomputer.It is assumed that the download program is stored in advance in the mainapparatus.

It should be noted here that the program medium is a storage mediumarranged to be separable from the main body. The storage medium may be,for example, a tape, such as a magnetic tape or a cassette tape; amagnetic disk, such as a flexible disk or a hard disk, or an opticaldisk, such as CD-ROM/MO/MD/DVD; a card, such as an IC card (memory card)or an optical card; or a semiconductor memory, such as a mask ROM/EPROM(erasable programmable read-only memory)/EEPROM (electrically erasableprogrammable read-only memory)/flash ROM. All these storage media hold aprogram in a fixed manner.

Alternatively, since the present embodiment is a system configurationconnectable to communication networks including the Internet, theprogram medium may be a medium carrying the program code in a flowingmanner as in the downloading of a program over a communication network.Further, when the program code is downloaded over a communicationsnetwork in this manner, the download program may be stored in advance inthe main apparatus or installed from another storage medium. The presentinvention can be realized in the form of a computer data signal,embedded in a carrier wave, in which the program code is embodiedelectronically. The storage medium is read by a digital color imageforming apparatus or a program reading device provided in a computersystem, whereby the aforementioned image processing method is executed.

As described above, an image processing apparatus according to thepresent invention is an image processing apparatus for generating imageprocessing data by performing image processing on input image data, forsupplying the image processing data to a job apparatus that executes animage print job, an image transmission job, or an image filing job, andfor supplying the image processing data to an image display device fordisplaying a preview, the image processing apparatus including: a blurprocess section for performing a blur process on image processing datato be supplied to the image display device.

According to the foregoing arrangement, the job apparatus, whichexecutes an image print job, an image transmission job, or an imagefiling job, and the image display device, which displays a preview, areeach supplied with image processing data. It should be noted here thatimage processing data to be supplied to the image display device aresubjected to a blur process. Therefore, the blur process makes itpossible to display an image while inhibiting deterioration in imagequality even if a preview is displayed by an image display device whoseresolution is lower than the resolution at which the input image datahave been read.

Thus, the image processing apparatus according to the present inventionperforms a blur process on image processing data to be supplied to theimage display device, i.e., on data on a text and/or line art image aswell as a picture image, and as such, can inhibit deterioration in imagequality by reducing a lack of image information at the time of a previewdisplay on the image display device. This makes it possible to obtain aneasily viewable preview display.

In addition to the foregoing arrangement, the image processing apparatusaccording to the present invention may be arranged to further include aspatial filter section for performing a filter process on imageprocessing data to be supplied to the job apparatus, wherein the spatialfilter section serves as the blur process section to perform, as theblur process, a filter process for smoothing the image processing datato be supplied to the image display device.

According to the foregoing arrangement, the spatial filter section,provided in the image processing apparatus, which performs a filterprocess on image processing data to be supplied to the job apparatus canbe used to perform a blur process on the image processing data to besupplied to the image display device. This eliminates the need for aseparate circuit for blurring the image processing data to be suppliedto the image display device, thus inhibiting an increase in circuit sizeof the apparatus.

In addition to the foregoing arrangement, the image processing apparatusaccording to the present invention may be arranged such that the spatialfilter section includes a filter-coefficient selection section forselecting filter coefficients in accordance with resolution at which theinput image data have been read.

The foregoing arrangement makes it possible to select different filtercoefficients according to the resolution at which the input image datahave been read, thus making it possible to obtain image quality suitablefor each level of resolution.

In addition to the foregoing arrangement, the image processing apparatusaccording to the present invention may be arranged to further include anenlarging/reducing section for performing an enlarging/reducing processon image processing data to be supplied to the job apparatus, whereinthe enlarging/reducing section performs an interpolation process inaccordance with resolution and screen size of the image display device.

According to the foregoing arrangement, the enlarging/reducing section,provided in the image processing apparatus, which performs anenlarging/reducing process on image processing data to be supplied tothe job apparatus is used to perform an interpolation process on theimage processing data to be supplied to the image display device. Thisinterpolation process is performed in accordance with the resolution andscreen size of the image display device. This eliminates the need for aseparate circuit for performing, in accordance with the resolution andscreen size of the image display device, an interpolation process ofdownsampling the image processing data to be supplied to the imagedisplay device, thus inhibiting an increase in circuit size of theapparatus. Further, the interpolation process achieves a reduction insize of image data, thus making it possible to shorten the amount oftime it takes to display image processing data to be displayed by theimage display device.

In addition to the foregoing arrangement, the image processing apparatusaccording to the present invention may be arranged such that theenlarging/reducing section severs as the blur process section toperform, as the blur process, an interpolation process that maintainssmoothness in tone of the image processing data to be supplied to theimage display device.

According to the foregoing arrangement, the enlarging/reducing sectionprovided in the image processing apparatus can be used to perform, onthe image processing data to be supplied to the image display device, ablur process, i.e., an interpolation process that maintains smoothnessin tone of the image processing data. This eliminates the need for aseparate circuit for blurring the image processing data to be suppliedto the image display device, thus inhibiting an increase in circuit sizeof the apparatus.

In addition to the foregoing arrangement, the image processing apparatusaccording to the present invention may be arranged such that theenlarging/reducing section performs the interpolation process with useof a bilinear or bicubic method. According to the foregoing arrangement,the interpolation process in the enlarging/reducing section with use ofthe bilinear or bicubic method makes it possible to effectively performa blur process, thus making it possible to inhibit a thin spot or breakin line or text in a preview display.

As described above, an image forming apparatus according to the presentinvention includes: any one of such image processing apparatuses asdescribed above; the job apparatus; and an image display device fordisplaying a preview of the image processing data. The image formingapparatus according to the present invention executes an image printjob, an image transmission job, or an image filing job on imageprocessing data obtained by performing image processing on input imagedata, and displays a preview of the image processing data on the imagedisplay device together with the execution of the job. Since the imageprocessing data to be supplied to the image display device have beensubjected to a blur process, the preview is displayed with inhibiteddeterioration in image quality. Therefore, the foregoing arrangementmakes it possible to provide an image forming apparatus capable ofdisplaying a preview while inhibiting deterioration in image quality.

As described above, an image processing method according to the presentinvention is an image processing method including a step of generatingimage processing data by performing image processing on input imagedata, a step of supplying the image processing data to a job apparatusthat executes an image print job, an image transmission job, or an imagefiling job, and a step of supplying the image processing data to animage display device for displaying a preview, the image processingmethod comprising: a blur process step of performing a blur process onimage processing data to be supplied to the image display device.

The foregoing method, which brings about the same effect as the aboveimage processing apparatus, makes it possible to display a preview whileinhibiting deterioration in image quality.

Further, an image processing apparatus of the present invention can berealized by a computer. In this case, an image processing program forrealizing the image processing apparatus on a computer by causing thecomputer to function as each section of the image processing apparatusand a computer-readable storage medium containing the image processingprogram are also encompassed in the scope of the present invention.

These arrangements make it possible to realize the same effect as theimage processing apparatus by causing a computer to read and execute theimage processing program.

The embodiments and concrete examples of implementation discussed in theforegoing detailed explanation serve solely to illustrate the technicaldetails of the present invention, which should not be narrowlyinterpreted within the limits of such embodiments and concrete examples,but rather may be applied in many variations within the spirit of thepresent invention, provided such variations do not exceed the scope ofthe patent claims set forth below. Further, the numerical values outsideof the ranges shown in this specification are encompassed in the presentinvention as long as such ranges are rational ranges that do not defeatthe purpose of the present invention.

INDUSTRIAL APPLICABILITY

An image processing apparatus of the present invention can be used forapparatuses for processing image data and, in particular, formultifunction printers, copying machines, printers, and facsimilemachines.

The invention claimed is:
 1. An image processing apparatus forgenerating image processing data by performing image processing on inputimage data, for supplying the image processing data to a job apparatusthat executes an image print job, an image transmission job, or an imagefiling job, and for supplying the image processing data to an imagedisplay device for displaying a preview, the image processing apparatuscomprising: a blur process section for performing a blur process onimage processing data irrespective of the type of the image processingdata to be supplied to the image display device; a spatial filtersection for performing a filter process on image processing data to besupplied to the job apparatus, wherein the spatial filter section servesas the blur process section to perform, as the blur process, a filterprocess for smoothing the image processing data to be supplied to theimage display device and the spatial filter section includes afilter-coefficient selection section for selecting a matrix of filtercoefficients that become larger than one another toward a center of thematrix and become smaller than one another toward a periphery of thematrix.
 2. An image processing apparatus for generating image processingdata by performing image processing on input image data, for supplyingthe image processing data to a job apparatus that executes an imageprint job, an image transmission job, or an image filing job, and forsupplying the image processing data to an image display device fordisplaying a preview, the image processing apparatus comprising: a blurprocess section for performing a blur process on image processing datato be supplied to the image display device; and an enlarging/reducingsection for performing an enlarging/reducing process on image processingdata to be supplied to the job apparatus, the enlarging/reducing sectionperforming an interpolation process on the image processing data to besupplied to the image display device in accordance with resolution andscreen size of the image display device, and serving as the blur processsection to perform, as the blur process, an interpolation process thatmaintains smoothness in tone of the image processing data to be suppliedto the image display device.
 3. The image processing apparatus as setforth in claim 2, wherein the enlarging/reducing section performs theinterpolation process with use of a bilinear or bicubic method.
 4. Anon-transitory computer-readable storage medium containing an imageprocessing program for operating an image processing apparatus as setforth in claim 2, the image processing program causing a computer tofunction as each section of the image processing apparatus.
 5. An imageforming apparatus comprising: an image processing apparatus as set forthin claim 2; the job apparatus; and an image display device fordisplaying a preview of the image processing data.